- Class Number 2123
- Term Code 3330
- Class Info
- Unit Value 6 units
- Mode of Delivery In Person
- AsPr Fiona Beck
- AsPr Fiona Beck
- Class Dates
- Class Start Date 20/02/2023
- Class End Date 26/05/2023
- Census Date 31/03/2023
- Last Date to Enrol 27/02/2023
Discovering Engineering is the foundation course for engineering. The course invites students to discover engineering by tackling an open-ended design project, as well as learning a variety of essential technical and non-technical skills. The major project for the course is to work in teams to design and build a robot rover that can autonomously navigate around a maze.
Throughout the course, students undertake a variety of learning activities that introduce the key engineering concepts that are needed to successfully complete the project. Students learn about the engineering design process, including understanding what is needed in a project, generating concepts, prototyping, analysing, and implementing a solution. Students work in teams, allowing them to develop their collaboration and communication skills, as well as their project management skills. This is complemented by learning about the importance of reflective and ethical professional practice. At the same time students will also learn about basic electronics, coding and problem solving, providing a range of fundamental skills needed by a modern engineer.
Upon successful completion, students will have the knowledge and skills to:
- Demonstrate research into engineering concepts, technology and contexts.
- Select and use appropriate engineering tools to model and analyse engineering components.
- Design a solution to an open-ended problem using an engineering process.
- Identify responsibilities within an engineering team in relation to professional practice.
- Communicate engineering concepts and solutions effectively using different media to professional and other audiences.
- Demonstrate self-reflection and evaluation of ideas
The ANU invests in transformative research with the goal of finding solutions for some of the world's biggest and most important problems, through a variety of research initiatives, including ANU Grand Challenges Scheme. While these types of problems draw on expertise across the disciplines at ANU, the engineering design process necessarily plays a central role in such projects. Dr Beck is the Convenor of the transdisciplinary Hydrogen Fuels project, part of the ANU’s Zero Carbon Energy for the Asia Pacific Grand Challenge. She integrates learnings from this project into her teaching of Discovering Engineering, including how to foster creative teamwork, novel approaches to problem solving, and how to communicate to a wide range of stakeholders.
Examination Material or equipment
There is no exam for this course.
Whether you are on campus or studying remotely, there are a variety of online platforms you will use to participate in your study program. These could include videos for lectures and other instruction, two-way video conferencing for interactive learning, email and other messaging tools for communication, interactive web apps for formative and collaborative activities, print and/or photo/scan for handwritten work and drawings, and home-based assessment.
ANU outlines recommended student system requirements to ensure you are able to participate fully in your learning. Other information is also available about the various Learning Platforms you may use.
It is recommended that you attend an induction for the ANU/Engineering MakerSpace to access these facilities for your project work.
Labs and project work in this course use an Arduino Uno microcontroller and the open-source Arduino Software (IDE). Hardware and electronics for the course will be supplied. The software can be downloaded from: https://www.arduino.cc/en/software Computers will require a USB connection to work with an Arduino Uno microcontroller.
Students will be given feedback in the following forms in this course:
- written comments
- verbal comments
- feedback to whole class, groups, individuals, focus group etc
ANU is committed to the demonstration of educational excellence and regularly seeks feedback from students. Students are encouraged to offer feedback directly to their Course Convener or through their College and Course representatives (if applicable). Feedback can also be provided to Course Conveners and teachers via the Student Experience of Learning & Teaching (SELT) feedback program. SELT surveys are confidential and also provide the Colleges and ANU Executive with opportunities to recognise excellent teaching, and opportunities for improvement.
|Week/Session||Summary of Activities||Assessment|
|1||Lecture 1A: Introduction to course Lecture 1B: Solving open ended and ill defined problems||Quiz #1|
|2||Lecture 2A: ANUSEP: Where to start tackling a problem Lecture 2B: Intro to electronics and programming with Arduino Electronics/Arduino lab 0: Introduction - blink||Quiz #2 Rover project documentation released|
|3||Lecture 3A: ANUSEP: Generating ideas Lecture 3B: Communication and project management Workshop: Ready, steady, rover! Getting started on the rover project||Quiz #3 Milestone 1: Team charter 1%|
|4||Lecture 4A: Public holiday - no lecture Lecture 4B: Programming 1 Electronics/Arduino lab 1: H-bridge and motor control||Quiz #4 Lab quiz #1 5% Design Report 10%|
|5||Lecture 5A: ANUSEP: Testing your ideas Lecture 5B: Programming 2 Electronics/Arduino lab 2: Programming for input and output, debugging||Quiz #5 Lab quiz #2 5%|
|6||Lecture 6A: ANUSEP: Preliminary design Lecture 6B: Teamwork and creativity Group Update: Rover concept||Quiz #6 Milestone 2: Conceptual design 2%|
|7||Lecture 7A: ANUSEP: Preliminary design and project management Lecture 7B: Programming 3 Computer Lab 3: Sonar||Quiz #7 Lab quiz #3 5% Team member contribution (TMC) 1 - due in teaching break|
|8||Lecture 8A: ANUSEP: Understanding sources of error and how to design around it Lecture 8B: Public holiday - no lecture Workshop: Rover -in-motion. Demonstrating and initial testing of your rover||Quiz #8 Milestone 3: Rover-in-motion 1%|
|9||Lecture 9A: ANUSEP: Communicating your design Lecture 9B: Ethics in Engineering Group update - Rover validation and testing plan||Quiz #9 Milestone 4: Detailed design and testing plan 1%|
|10||Lecture 10A: Reflection in Engineering Lecture 10B: Guest Lecture Group updates and rover testing (drop-in)||Quiz #10|
|11||Lecture 11A: Opportunities and Graduate Attributes Lecture 11B: ANUSEP: doing a better job next time Workshop: Final Rover Testing||Quiz #11 Rover testing 10%|
|12||Lecture 12A: No lecture Lecture 12B: No lecture - Drop-in session for rover report||Quiz #12 Rover design report 25%|
|13||Reflection 25% TMC 2|
Students will register for two 2-hour workshops each week via MyTimetable. Workshops and computer labs will both take place during this timeslot.
|Assessment task||Value||Learning Outcomes|
|Weekly quizzes||10 %||1, 2|
|Design report||10 %||1, 3, 5, 6|
|Lab quizzes||15 %||2, 5|
|Rover milestones||5 %||2, 3, 4, 5|
|Rover testing||10 %||2, 3, 4, 5|
|Rover design report||25 %||1, 2, 3, 4, 5|
|Reflection||25 %||1, 5, 6|
* If the Due Date and Return of Assessment date are blank, see the Assessment Tab for specific Assessment Task details
ANU has educational policies, procedures and guidelines , which are designed to ensure that staff and students are aware of the University’s academic standards, and implement them. Students are expected to have read the Academic Integrity Rule before the commencement of their course. Other key policies and guidelines include:
- Academic Integrity Policy and Procedure
- Student Assessment (Coursework) Policy and Procedure
- Special Assessment Consideration Guideline and General Information
- Student Surveys and Evaluations
- Deferred Examinations
- Student Complaint Resolution Policy and Procedure
- Code of practice for teaching and learning
The ANU is using Turnitin to enhance student citation and referencing techniques, and to assess assignment submissions as a component of the University's approach to managing Academic Integrity. For additional information regarding Turnitin please visit the Academic Skills website. In rare cases where online submission using Turnitin software is not technically possible; or where not using Turnitin software has been justified by the Course Convener and approved by the Associate Dean (Education) on the basis of the teaching model being employed; students shall submit assessment online via ‘Wattle’ outside of Turnitin, or failing that in hard copy, or through a combination of submission methods as approved by the Associate Dean (Education). The submission method is detailed below.
Moderation of Assessment
Marks that are allocated during Semester are to be considered provisional until formalised by the College examiners meeting at the end of each Semester. If appropriate, some moderation of marks might be applied prior to final results being released.
There is no exam for this course.
Assessment Task 1
Learning Outcomes: 1, 2
The weekly quiz will be due by the close of business every Friday. Each will be worth 1% with the best 10 grades counting towards the course total. Students will have two attempts at each quiz. Questions will cover material from the lectorials, workshops, and laboratories.
Value: 10% (best 10 of 12)
Format: Multiple choice on-line quiz in Wattle, two attempts on each
Assessment Task 2
Learning Outcomes: 1, 3, 5, 6
This individual report will develop your ability to research a topic in an engineering context and evaluate the information relevant to the issue. It will also develop skills in scoping a design problem, determining design criteria for the solution, and generating concepts to address these design criteria. You will then evaluate your concepts and communicate your results to a general technical audience. You should communicate your findings in a manner that shows you have taken information from more than one source, filtered, combined, and evaluated that information to form logical conclusions.
Please see the assignment sheet in Wattle for further information on the design topic and the marking rubric.
Format: Written report of 5-8 pages
Assessment Task 3
Learning Outcomes: 2, 5
The lab quizzes will assess a students understanding of the material taught in the computer laboratories and how the labs link to the rover project.
Value: 15% (3 x 5%) in weeks 4, 5 and 7
Format: Multiple choice and short answer on-line quiz in Wattle
Assessment Task 4
Learning Outcomes: 2, 3, 4, 5
The rover milestones are small deliverable that are spaced through the semester to help students achieve the goals of the main project of the course, to build an autonomous maze solving robot. They support teams to complete the project over a ten week timeframe whilst providing regular feedback from the teaching team.
Milestone 1: Team charter - exercise completed and graded during week 3 workshops (1%)
Milestone 2: Conceptual design - report during week 6 workshops(2%)
Milestone 3: Rover-in-motion - report and demonstration during week 8 workshops (1%)
Milestone 4: Detailed design and testing plan - report during week 9 workshop (1%)
Value: 5% (3 x 1%, 1 x 2%)
Format: Short written report or in-class demonstration
Feedback: verbal feedback during workshops
Assessment Task 5
Learning Outcomes: 2, 3, 4, 5
Rover testing determines if the teams design can achieve the goals of the rover project. Testing is broken down into a series of functions that are required to autonomously navigate a maze.
For further information on rover testing please see the Rover project over view on Wattle.
Format: In-class demonstration from week 8, final testing in week 11
Assessment Task 6
Learning Outcomes: 1, 2, 3, 4, 5
Rover design report
The purpose of this report is to document the final design solution for the Rover. It will communicate your solution to audiences outside your group with detail that would allow the reader to understand the reasons for your design choice and enable them to build a rover to your teams design. The report will include the design requirements or specification of the rover including the rationale behind critical design decisions. It will document the design of the rover structure, electronics and logic for operation including ?a summary of the circuit simulation for the rover design. The report will document the testing and validation of the design including design changes made?because of?testing and validation and an evaluation of the final design.
Please see the assignment sheet in Wattle for further information on report and the marking rubric.
Format: Written report of 10 pages
Assessment Task 7
Learning Outcomes: 1, 5, 6
Engineers use reflection to critically assess the process and outcomes throughout a project. It can help to analyse lessons learnt; what worked well, what did not, and how it could be improved next time. Reflection builds on, and is an application of, critical thinking. In addition, self-assessment is an important part of developing as an engineer. In this assignment students will reflect on three different aspects of the course:
- The rover project;
- Your learning experience and how it related to the Engineers Australia competencies
- Ethics in engineering
Please see the assignment sheet in Wattle for further information on the reflection and the marking rubric.
Format: Written reflection, 5 pages
Due date: The reflection will be submitted during the exam period.
Academic integrity is a core part of the ANU culture as a community of scholars. The University’s students are an integral part of that community. The academic integrity principle commits all students to engage in academic work in ways that are consistent with, and actively support, academic integrity, and to uphold this commitment by behaving honestly, responsibly and ethically, and with respect and fairness, in scholarly practice.
The University expects all staff and students to be familiar with the academic integrity principle, the Academic Integrity Rule 2021, the Policy: Student Academic Integrity and Procedure: Student Academic Integrity, and to uphold high standards of academic integrity to ensure the quality and value of our qualifications.
The Academic Integrity Rule 2021 is a legal document that the University uses to promote academic integrity, and manage breaches of the academic integrity principle. The Policy and Procedure support the Rule by outlining overarching principles, responsibilities and processes. The Academic Integrity Rule 2021 commences on 1 December 2021 and applies to courses commencing on or after that date, as well as to research conduct occurring on or after that date. Prior to this, the Academic Misconduct Rule 2015 applies.
The University commits to assisting all students to understand how to engage in academic work in ways that are consistent with, and actively support academic integrity. All coursework students must complete the online Academic Integrity Module (Epigeum), and Higher Degree Research (HDR) students are required to complete research integrity training. The Academic Integrity website provides information about services available to assist students with their assignments, examinations and other learning activities, as well as understanding and upholding academic integrity.
You will be required to electronically sign a declaration as part of the submission of your assignment. Please keep a copy of the assignment for your records. Unless an exemption has been approved by the Associate Dean (Education) submission must be through Turnitin.
For some forms of assessment (hand written assignments, art works, laboratory notes, etc.) hard copy submission is appropriate when approved by the Associate Dean (Education). Hard copy submissions must utilise the Assignment Cover Sheet. Please keep a copy of tasks completed for your records.
Individual assessment tasks may or may not allow for late submission. Policy regarding late submission is detailed below:
- Late submission not permitted. If submission of assessment tasks without an extension after the due date is not permitted, a mark of 0 will be awarded.
- Late submission permitted. Late submission of assessment tasks without an extension are penalised at the rate of 5% of the possible marks available per working day or part thereof. Late submission of assessment tasks is not accepted after 10 working days after the due date, or on or after the date specified in the course outline for the return of the assessment item. Late submission is not accepted for take-home examinations.
The Academic Skills website has information to assist you with your writing and assessments. The website includes information about Academic Integrity including referencing requirements for different disciplines. There is also information on Plagiarism and different ways to use source material.
Assignments - Feedback and grades for all assignments will be available via the Wattle gradebook
Rover milestones - verbal feedback will be provided by your tutor during your group updates. Grades for milestones will be recorded in the gradebook within 10 working days after the workshop.
Final assessment - Marks for the assignment will not be released separately (as occurs for final exams). Feedback will be available at the end of the exam period via the Wattle gradebook.
Extensions and Penalties
Extensions and late submission of assessment pieces are covered by the Student Assessment (Coursework) Policy and Procedure. Extensions may be granted for assessment pieces that are not examinations or take-home examinations. If you need an extension, you must request an extension in writing on or before the due date. If you have documented and appropriate medical evidence that demonstrates you were not able to request an extension on or before the due date, you may be able to request it after the due date.
Distribution of grades policy
Academic Quality Assurance Committee monitors the performance of students, including attrition, further study and employment rates and grade distribution, and College reports on quality assurance processes for assessment activities, including alignment with national and international disciplinary and interdisciplinary standards, as well as qualification type learning outcomes.
Since first semester 1994, ANU uses a grading scale for all courses. This grading scale is used by all academic areas of the University.
Support for students
The University offers students support through several different services. You may contact the services listed below directly or seek advice from your Course Convener, Student Administrators, or your College and Course representatives (if applicable).
- ANU Health, safety & wellbeing for medical services, counselling, mental health and spiritual support
- ANU Access and inclusion for students with a disability or ongoing or chronic illness
- ANU Dean of Students for confidential, impartial advice and help to resolve problems between students and the academic or administrative areas of the University
- ANU Academic Skills and Learning Centre supports you make your own decisions about how you learn and manage your workload.
- ANU Counselling Centre promotes, supports and enhances mental health and wellbeing within the University student community.
- ANUSA supports and represents undergraduate and ANU College students
- PARSA supports and represents postgraduate and research students
I am an applied physicist whose research is focused on advancing the clean energy transition. I lead a research group working to integrate optoelectronics and nanophotonics to develop novel renewable energy technologies. I am also the Convenor of the Hydrogen Fuels project for ZCEAP - Zero-Carbon Energy for the Asia-Pacific, ANU Energy Change Institute Grand Challenge, working with a transdisciplinary team from across ANU to help transform Australia into a leading exporter of renewable fuels in our region.
My research spans the boundary between nano-scale optics and photoelectrochemical/optoelectronic device design: harnessing an improved understanding of light-matter interactions to investigate new ways to convert light to other forms of energy. My research group brings together expertise in numerical simulations, device design and fabrication, and advanced characterisation to demonstrate proof-of-concept devices with the potential to impact a range of applications; including renewable fuels such as hydrogen.
For more info on what I do, and why, see:
AsPr Fiona Beck